New paradigm for sand liquefaction under cyclic loadings

IF 6.9 1区工程技术 Q1 ENGINEERING, GEOLOGICAL

Engineering Geology Pub Date : 2025-03-21 DOI:10.1016/j.enggeo.2025.108041

Guoxing Chen , Xing Xiao , Qi Wu , You Qin , Hongmei Gao , Chengshun Xu , Armin W. Stuedlein

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Abstract

Despite over six decades of field and laboratory investigations, theoretical studies, and advances in constitutive modeling, questions remain on the fundamental issues concerning liquefaction mechanisms, the collective influence of multiple factors on excess pore water pressure (EPWP) generation, and liquefaction triggering criteria. This paper presents the general apparent viscosity- and average flow coefficient-based methodology for quantifying the solid-liquid phase-change process of liquefiable soil under undrained cyclic loading. The analysis reveals that the evolution of the soil particle-fabric system is the fundamental physico-mechanical mechanism behind EPWP generation in a liquefiable soil, with the accompanying change in soil physical state serving as the intrinsic mechanism driving EPWP generation. The study further identifies the physico-mechanical foundations of EPWP generation, as well as the inherent causes and a unified quantitative characterization of the coupled influences of multiple factors on EPWP generation. This work presents the novel observation that the marginal peak excess pore pressure ratio (r_u,pm) between the solid-liquid mixed phase and the liquid phase of liquefiable soil can be identified accurately and that r_u,pm is characterized by its inherent robustness. A r_u,pm value of 0.90 can be used as a liquefaction triggering criterion for soils both in laboratory element tests and in the field. Another original finding is that the liquefaction triggering resistance curve is the threshold state curve between solid-liquid mixed phase and transiently liquid phase of a liquefiable soil and is unique for a specific initial physical state. The definitions of liquefaction triggering and corresponding liquefaction triggering resistance are clear and unambiguous and have the same physico-mechanical basis. The insights obtained in this paper will potentially enable the scientific and engineering communities to reinterpret the liquefaction mechanism, its evaluation, and liquefaction mitigation strategies.

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循环荷载作用下砂土液化的新范式

尽管经过了60多年的现场和实验室调查、理论研究以及本构模型的进步，但关于液化机制、多种因素对超孔隙水压力（EPWP）产生的共同影响以及液化触发标准等基本问题仍然存在疑问。本文提出了基于表观黏度和平均流动系数的一般方法来量化不排水循环荷载作用下可液化土固液相变过程。分析表明，土壤颗粒-组构系统的演化是液化土中EPWP生成的基本物理力学机制，伴随而来的土壤物理状态变化是驱动EPWP生成的内在机制。进一步明确了EPWP生成的物理力学基础，以及多因素耦合影响EPWP生成的内在原因和统一的定量表征。本文提出了一种新的观测结果，即可以准确地识别可液化土固液混合相和液相之间的边际峰值超孔压比（ru,pm），并且ru，pm具有固有的鲁棒性。ru，pm值为0.90可作为室内和现场土壤液化触发判据。另一个独创性的发现是，液化触发阻力曲线是可液化土固液混合相与瞬态液相之间的阈值状态曲线，对于特定的初始物理状态是唯一的。液化触发和相应的液化触发阻力的定义是明确的，具有相同的物理力学基础。本文中获得的见解将有可能使科学界和工程界重新解释液化机制，其评估和液化缓解策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Engineering Geology 地学-地球科学综合

CiteScore

13.70

自引率

12.20%

发文量

327

审稿时长

5.6 months

期刊介绍： Engineering Geology, an international interdisciplinary journal, serves as a bridge between earth sciences and engineering, focusing on geological and geotechnical engineering. It welcomes studies with relevance to engineering, environmental concerns, and safety, catering to engineering geologists with backgrounds in geology or civil/mining engineering. Topics include applied geomorphology, structural geology, geophysics, geochemistry, environmental geology, hydrogeology, land use planning, natural hazards, remote sensing, soil and rock mechanics, and applied geotechnical engineering. The journal provides a platform for research at the intersection of geology and engineering disciplines.